DE19748081A1 - Method and device for image reconstruction in a multi-section computer tomography system - Google Patents

Description

The invention relates generally to a computer tomo graphic illustration and in particular a registration directional construction and an image reconstruction at a more cut computer tomography system.

In at least one known computer tomography system structure (CT system structure) projects an X-ray swell a fan-shaped beam directed in parallel is that he is in an X-Y plane of a Cartesian Coordina tensystems, which is generally as a mapping plane or surface referred to as. The X-ray beam falls through the object to be imaged, such as a patient. After the Beam is subdued by the object, it strikes a Arrangement or an array of radiation detection devices The intensity of the ge detected on the detection array attenuated radiation depends on the attenuation of the x-ray through the object. Any capture element of the array generates a separate electrical signal that is a measure of Beam attenuation is at the detection location. The damping dimensions of all data collection devices are generated separately tion of a transmission profile recorded.

Known third-generation CT systems rotate the x-ray source and the detection array with one Barrel storage (gantry) in the image level and around the image the object, so that the angle at which the X-ray cross beam cuts the object, changes constantly. A Group of x-ray attenuation measures, i. H. Projection data from the detection array at a barrel bearing angle referred to as a view. A scan of the item includes a set of views at different barrel bearing angles during one revolution of the X-ray source and the Er detection device. With an axial scanning the Processed projection data to form an image that a two-dimensional section through the object ent  speaks. A method of reconstructing an image a set of projection data is known in the art as ge Filtered rear projection method called. With this The attenuation measures from a scan in whole numbers, so-called CT numbers or Hounsfield units, converted that correspond to the control of the brightness of a corresponding picture element on a cathode ray tube display device can be used.

A spiral scan can be used to reduce the total scan time be performed. To perform a spiral abta The patient is moved while the data for the previous written number of cuts can be recorded. At a Such a system turns a single coil from a fan beam helix scan generated. That through the fan beam trained helix provides projection data from which Bil which are reconstructed in every prescribed section can.

Multi-slice CT systems are used to obtain data for one use increased number of cuts during a scan det. Known multi-cut systems typically contain Er frame devices, generally as two-dimensional le detection devices (2-D detection devices) be are known. With such two-dimensional detection directions forms a large number of detection cells separate Columns or channels, and the columns are arranged in rows net. Each row of detection devices forms a se separate cut. For example, a two-cut detection has set up two rows of detection cells, and a four-cut detector has four rows of Er conviction cells. During a multi-slice scan several rows of detection cells simultaneously through the X-ray hit and therefore data for multiple cuts receive.  

So far, it was believed that adding cuts, d. H. Rows of detection cells, required for a CT system It is necessary to significantly change the hardware and software. A data acquisition system typically samples analog data from each detection cell and converts the data into digita le signals for subsequent processing. When adding from rows of detection cells to a detection array must therefore the data acquisition system for sampling data from the to additional detection cells can be modified. Accordingly for a two-section system, the data acquisition system for Ab scanning of twice as many detection cells compared to be modified in a single cut system. Alike the data acquisition system must be for a four-section system Sampling of four times as many detection cells compared be modified with a single cut system.

Furthermore, by increasing the number of registration cells len the amount of data that is transmitted via the drum bearing contact ring must be increased. Such an increased amount of data will preferably in the same time frame via the contact ring transferred in which data from a system with less Er version cells are transmitted, and therefore must be in the increase The number of detection cells depends on the data transmission range te are typically increased via the contact ring.

The invention is therefore based on the object of detection rows of cells to a computer tomography system without that Requires substantial modifications both with respect to Software as well as hardware in known systems inflict. Such a multi-row system should also without Ver deterioration in the overall image quality.

These and other tasks can be done in a multi-cut system be solved, which in one embodiment is a partially includes a coupled acquisition array. According to one embodiment Example of the invention is at least one channel Coupled multi-channel acquisition arrays, so that such  Channel only transmits a data measurement signal when on it X-ray hits. In one embodiment, there are recording cells in at least one column of cells, or a Ka nal, taken together or coupled in the z direction, see above that for the mechanically coupled cells a channel signal of is transferred to the detection cells via the contact ring. There are no other detection cells in adjacent channels coupled, so that such detection cells separate data provide measurement signals. That is, the coupled capturing Solution cells are between non-coupled detection cells arranged. According to another embodiment, the Kopp using a single detection cell that is twice as long as other cells in the z direction.

The signal distribution in the z direction for the transmitted coupled channel signal is determined using signals obtained from the adjacent uncoupled detection cells. In a two-section system with detection series A and B, the signal distribution in the z direction for the coupled channel i is estimated as follows:

in which

S _i the signal transmitted, for example transmitted, from the coupled channel i,
S _{Ai is} a non-coupled detection cell signal obtained from channel i for the detection row A,
S _{Bi is} a non-coupled detection cell signal received from channel i for the detection row B,
S ' _{Ai is} an estimated coupled acquisition cell signal on channel i for acquisition series A and
S ' _{Bi is} an estimated coupled acquisition cell signal on channel i for acquisition row B.

By coupling channels as described above additional rows of acquisition cells to a CT system oh ne the requirement of essential hardware and software modes fications with known systems are added. Au Furthermore, it is not assumed that such a coupling is Overall image quality reduced.

The invention is described below with reference to exemplary embodiments len with reference to the accompanying drawing Lich described. Show it:

Fig. 1 is a pictorial representation of a computer tomography imaging system,

Fig. 2 is a schematic block diagram of the presented in FIG. 1 Darge system,

Fig. 3 is a schematic representation of a two-section detection array according to an embodiment and

Fig. 4 is a schematic representation of a two-section detection array according to another embodiment.

Figs. 1 and 2 show a computer tomography-Ab education system (CT-imaging system) 10 including a gantry (gantry) 12, which is a CT scanner of the drit th generation. The barrel storage 12 has an X-ray source 14 which projects an X-ray beam 16 in the direction of a detection array 18 on the opposite side of the barrel storage 12 . The detection array 18 is formed from detection elements 20 , which together receive the projected x-rays that pass through a medical patient 22 . Each sensing element 20 generates an electrical signal that represents the intensity of an incident of the x-ray beam and thus the attenuation of the beam when it passes through the patient 22 . During a scan for the acquisition of X-ray projection data, the barrel bearing 12 and the components attached to it rotate about a center of rotation 24 .

The rotation of the barrel bearing 12 and the operation of the X-ray source 14 are controlled by a control device 26 of the CT system 10 . The control device 26 contains ei ne X-ray control device 28 which supplies the X-ray source 14 with energy and time signals, and a drum bearing motor control device 30 which controls the rotational speed and position of the drum bearing 12 . A data acquisition system (DAS) 32 in the controller 26 samples analog data from the sensing elements 20 and converts the data into digital signals for subsequent processing. An image reconstruction device 34 receives sampled and digitized x-ray data from the data acquisition system 32 and performs high speed image reconstruction. The reconstructed image is fed to a computer 36 as an input signal, which stores the image in a mass storage device 38 .

Computer 36 also receives commands and scanning parameters from an operator via control panel 40 which has a keyboard. An associated cathode ray tube display device 42 enables the operator to monitor the reconstructed image and other data from the computer 36 . The commands and parameters supplied by the operator are used by the computer 36 to form control signals and information for the data acquisition system 32 , the X-ray control device 28 and the drum motor control device 30 . The computer 36 also operates a table motor control device 44 , which controls a motorized table 46 for positioning the patient 22 in the barrel bearing 12 . In particular, the table 46 moves sections of the patient 22 through a barrel opening 48 .

The known spiral reconstruction algorithms can be used in all common as spiral extrapolation (HE) or spiral interpole tion (HI) algorithms are classified. With these algo is typically a weighting factor in the Projection data used to reconstruct an image. This weighting factor is generally based on both Fan angle as well as the viewing angle.

The following description of signal estimation, image quality and coupled acquisition arrays sometimes refers in particular to multi-slice CT scanners, which typically include acquisition arrays with two, four or more rows of acquisition elements or acquisition cells. However, the coupled acquisition arrays and signal estimation are not limited to exercise in conjunction with only two and four section scanners, but can also be used with other multi-section CT scanners with multiple or fewer rows of detection cells. Furthermore, the present signal estimation is not directed towards a special spiral image reconstruction algorithm. Rather, the present signal estimation can be used in conjunction with many different types of spiral weighting factors. In addition, the present signal estimate can be used in conjunction with axial scans, ie, in one step and capture mode. Furthermore, in one embodiment, the signal estimation is implemented in the computer 36 and processes, for example, data stored in the mass storage device 38 . However, many other alternative implementations are also possible.

Fig. 3 shows a two-sectional or twin system detecting array 50 according to an embodiment. The detection array 50 is a two-dimensional detection array with two rows A and B of detection cells 52 which are shifted in the z-direction. Each column of detection cells 52 in the z direction defines a channel C ₁ to C ₂₅ . Accordingly, FIG. 3 illustrates a twin system with 25 channels.

Detection cells 52 in at least one of the channels C ₁ to C ₂₅ are coupled or combined or combined in the z direction. Specifically, twelve (12) channels C ₂ , C ₄ , C ₆ , C ₈ , C ₁₀ , C ₁₂ , C ₁₄ , C ₁₆ , C ₁₈ , C ₂₀ , C _22, and C ₂₄ contain coupled sensing cells 52 . The channels containing coupled sensing cells are sometimes referred to as coupled channels. However, the remaining thirteen (13) channels C ₁ , C ₃ , C ₅ , C ₇ , C ₉ , C ₁₁ , C ₁₃ , C ₁₅ , C ₁₇ , C ₁₉ , C ₂₁ , C ₂₃ and C ₂₅ contain uncoupled detection cells 52 . The channels containing uncoupled detection cells are also referred to as uncoupled channels. Each coupled channel C ₂ , C ₄ , C ₆ , C ₈ , C ₁₀ , C ₁₂ , C ₁₄ , C ₁₆ , C ₁₈ , C ₂₀ , C ₂₂ and C ₂₄ is between two uncoupled channels C ₁ , C ₃ , C ₅ , C ₇ , C ₉ , C ₁₁ , C ₁₃ , C ₁₅ , C ₁₇ , C ₁₉ , C ₂₁ , C ₂₃ and C ₂₅ . For example, the coupled channel C _{2 is arranged} between the uncoupled channels C ₁ and C ₃ . Likewise, the coupled channel C _{10 is arranged} between the uncoupled channels C ₉ and C ₁₁ .

For one scan, the detection cells 52 of each uncoupled channel generate C ₁ , C ₃ , C ₅ , C ₇ , C ₉ , C ₁₁ , C ₁₃ , C ₁₅ , C ₁₇ , C ₁₉ , C ₂₁ , C ₂₃ and C ₂₅ separate data measurement signals, ie each uncoupled detection cell 52 generates a data measurement signal. The detection cells 52 of each coupled channel C ₂ , C ₄ , C ₆ , C ₈ , C ₁₀ , C ₁₂ , C ₁₄ , C ₁₆ , C ₁₈ , C ₂₀ , C ₂₂ and C ₂₄ each generate only one composite data signal per Ka nal. These data measurement signals can, for example, be stored in the data acquisition system 32 . Accordingly, the acquisition array 50 generates only thirty-eight (38) acquisition data measurement signals for one view of a scan.

To reconstruct images for each section, ie for each row A and B, the signal distribution in the z direction for each coupled channel C ₂ , C ₄ , C ₆ , C ₈ , C ₁₀ , C ₁₂ f C ₁₄ , C ₁₆ , C ₁₈ , C ₂₀ , C ₂₂ and C ₂₄ determined. In particular, separate data measurement signals for each detection cell 52 in row A and row B of the coupled channels C ₂ , C ₄ , C ₆ , C ₈ , C ₁₀ , C ₁₂ , C ₁₄ , C ₁₆ , C are generated before the generation of images ₁₈ , C ₂₀ , C ₂₂ and C ₂₄ estimated.

The signal distribution is according to one embodiment by in terpolation of the non-ge coupled channels by the detection cells 52 C _1, C _3, C _5, C _7, C _9, C _11, C _13, C _15, C _17, C _19, C ₂₁ , C ₂₃ and C ₂₅ determined data measurement signals determined. Those of the detection cells 52 in row A of the uncoupled channels C ₁ , C ₃ , C ₅ , C ₇ , C ₉ , C ₁₁ , C ₁₃ , C ₁₅ , C ₁₇ , C ₁₉ , C ₂₁ , C ₂₃ and C ₂₅ data measurement signals obtained are used to estimate separate data measurement signals for coupled detection cells 52 in row A of channels C ₂ , C ₄ , C ₆ , C ₈ , C ₁₀ , C ₁₂ , C ₁₄ , C ₁₆ , C ₁₈ , C ₂₀ , C ₂₂ and C ₂₄ interpolated. Similarly, the detection cells 52 in the row B of the uncoupled channels C ₁ , C ₃ , C ₅ , C ₇ , C ₉ , C ₁₁ , C ₁₃ , C ₁₅ , C ₁₇ , C ₁₉ , C ₂₁ , C ₂₃ and C _{25 received} data measurement signals for estimating separate data measurement signals for the coupled detection cells in the interpolated row B.

In a specific example, each coupled channel i generates a composite data measurement signal S _i . The signal distribution in the z direction for each coupled channel i is estimated as follows:

in which

S _{Ai is} a non-coupled detection cell signal obtained from channel i for the detection row A,
S _{Bi is} a non-coupled detection cell signal received from channel i for the detection row B,
S ' _{Ai is} an estimated coupled acquisition cell signal on channel i for acquisition series A and
S ' _{Bi is} an estimated coupled acquisition cell signal on channel i for acquisition series B.

Accordingly, separate data signal measurement estimates S ' _Ai for each row A and S' _Bi for each row B of the coupled channels C ₂ , C ₄ , C ₆ , C ₈ , C ₁₀ , C ₁₂ , C ₁₄ , C ₁₆ , C ₁₈ , C ₂₀ , C ₂₂ and C ₂₄ obtained.

Although the interpolation described above is linear Interpolation, other interpolations can be used be det. For example, interpolations can be second or even higher order can be used. It is accepted men that higher order interpolations have a higher Fre frequency component of any data signal measurement can preserve what contributes to the estimated signal measurements.  

The signal estimates S ' _Ai and S' _Bi are then used in conjunction with the generated uncoupled data measurement signals to generate an image of an object. That is, the signal estimates S ' _Ai and those through the detection cells 52 in the row A of the uncoupled channels C ₁ , C ₃ , C ₅ , C ₇ , C ₉ , C ₁₁ , C ₁₃ , C ₁₅ , C ₁₇ , C ₁₉ , C ₂₁ , C ₂₃ and C ₂₅ generated data measurement signals are processed to generate an image section for the row A of the detection cells 52 . Similarly, the signal estimates S ' _Ai and those through the detection cells in row B of the uncoupled channels C ₁ , C ₃ , C ₅ , C ₇ , C ₉ , C ₁₁ , C ₁₃ , C ₁₅ , C ₁₇ , C ₁₉ , C ₂₁ , C ₂₃ and C ₂₅ generated data measurement signals for processing an image section for the row B of the detection cells 52 processed. The signal estimates and the data measurement signals can, for example, be processed in accordance with the filtered back projection method.

According to a specific example, the signal distribution in the z direction, ie for row A and row B for the coupled channel C _{2, is determined in} accordance with the separate data measurement signals obtained by the detection cells 52 of the uncoupled channels C ₁ and C ₃ . That is, signals generated by the detection cells 52 in the row A of the uncoupled channels C ₁ and C ₃ each contribute to the estimation of the separate data measurement signal at the detection cell 52 in the row A of the coupled channel C ₂ . Similarly, the non-coupled channels C ₁ and C through the sense cells 52 in row B ₃ carry signal measurements obtained, respectively for estimating the Datenmeßsignals at the detection cell 52 in the row B of the coupled channel C ₂ at.

A coupled channel signal estimate can be based on the CT system calibration can be performed. The signal estimation can for example after beam hardening.

The acquisition array 50 described above and the coupled signal estimate reduce data transfer rates in twin slice helix reconstruction and facilitate the addition of rows of acquisition cells to a single slice CT system. As described above, the sense cells 52 of the array 50 generate only thirty-eight (38) data measurement signals instead of the fifty data measurement signals typically generated in a 25-channel twin editing system. Accordingly, in the above-mentioned twin editing system, the data acquisition system 32 scans only 1.5 times the amount of data scanned in a single editing system. Furthermore, it is believed that such a twin editing system does not significantly reduce image quality.

As described above, coupled detection channels C ₂ , C ₄ , C ₆ , C ₈ , C ₁₀ , C ₁₂ , C ₁₄ , C ₁₆ , C ₁₈ , C ₂₀ , C ₂₂ and C ₂₄ each contain two detection cells 52 . However, this description is only exemplary and not restrictive. In example, each coupled acquisition channel C ₂ , C ₄ , C ₆ , C ₈ , C ₁₀ , C ₁₂ , C ₁₄ , C ₁₆ , C ₁₈ , C ₂₀ , C ₂₂ and C ₂₄ consist of a lengthened detection cell, which is approximately is twice as long as each uncoupled sense cell 52 in the z direction. In this embodiment, each elongated, ie coupled, detection cell generates a data measurement signal S _i and the z distribution of such a signal can be estimated as described above.

Although the embodiment described above is a Variety of coupled channels in a twin section stem contains, it goes without saying that this structure can be changed many times. For example, less be coupled as twelve or more than twelve channels. Instead of the coupling of every second channel is equally possible for everyone third or fourth channel can be coupled. One of the like coupling in a four-section system or any a multi-cut system. You can also be coupled more than every second channel.  

Fig. 4 shows a twin system detector array 60 ei nem according to another embodiment. The detection array 60 contains two rows A and B of detection cells 62 , which are constructed in approximately twenty channels C ₁ to C ₂₄ . The detection cells 62 in adjacent channels C ₂ and C ₃ , C ₅ and C ₆ , C ₈ and C ₉ , C ₁₁ and C ₁₂ , C ₁₄ and C ₁₅ , C ₁₇ and C ₁₈ , C ₂₀ and C ₂₁ and C ₂₃ and C ₂₄ are each coupled, so that each such channel le diglich generates a composite data measurement signal. However, the detection cells 62 in the remaining channels C ₁ , C ₄ , C ₇ , C ₁₀ , C ₁₃ , C ₁₆ , C ₁₉ and C ₂₂ are not coupled, and they thus generate separate data measurement signals. Accordingly, the acquisition cells 62 of the twin system acquisition array 60 generate only thirty-two (32) data measurement signals during a scan instead of the forty-eight data measurement signals that will typically be obtained in a 24-channel twin editing system. Furthermore, the twin system acquisition array 60 generates only eight (8) data measurement signals more than a 24-channel single-cut system. Accordingly, the data acquisition system 32 samples only 1 1/3 times the amount of data sampled in a single-section system. The signal distribution in the z direction for each coupled channel C ₂ , C ₃ , C ₅ , C ₆ , C ₈ , C ₉ , C ₁₁ , C ₁₂ , C ₁₄ , C ₁₅ , C ₁₇ , C ₁₈ , C ₂₀ , C ₂₁ , C ₂₃ and C ₂₄ can be estimated according to equations (1) and (2).

As described above, channel coupling makes this easier Adding rows of detection cells to CT systems oh ne the need for substantial modifications of the known Systems. As described above, the data capture system, for example, only for the scanning of eight additional signals can be configured if one second row of twenty-four detection cells into one 24-channel single cut system is added. Furthermore can use a fifth row when using channel coupling from detection cells to a conventional four-section system can be added even without the data collection system  stem or the contact ring of such a system to modifi adorn.

As described above, although the former The described embodiments are based on twins Get cut scanners, other multi-cut scanners touch probes are used. For example multiple channels in a four-section scanner be coupled. Likewise, instead of adding a second row of detection cells into one Single cut system the coupling for adding an nth row from detection cells to an n-1 system.

From the previous description of the various designs Example, it can be seen that the tasks of the inventor be solved. Although the invention has been detailed written and illustrated, it is of course itself understandable that this is only for illustration and cannot be understood as a limitation. For example The CT system described here is a system of the third Generation in which both the X-ray source and also turn the detection device with the drum bearing. It can also do many other CT systems, including systems of fourth generation, where the Erfas a stationary full ring detection device tion is and only the X-ray source with the barrel ger turns. Although the invention here relates to twins relates to sectional scanning devices, the present Si gnal estimation also in connection with other section scans facilities are used. Although the above be wrote a simple linear interpolation on, the signal distribution in the z-direction can also be can be estimated by means of higher order interpolations.

According to the invention is a system for obtaining data measurement signals for generating a tomographic image of a counter was disclosed in a multi-section scan. This means,  Detection cells in at least one channel of a detection arrays are electrically linked, or coupled, so that the coupled channel to be transmitted via the drum bearing contact ring providing data measurement signal. The signal distribution in the z direction for the coupled channel is then under Ver use of signals determined by adjacent not coupled detection cells can be obtained.

Claims (19)

1. Device for obtaining data measurement signals for generating a tomography image of an object ( 22 ) in a tomography scan, the device having a detection array ( 50 ; 60 ) with
at least one coupled detection cell channel and
at least one uncoupled detection cell channel, the coupled detection cell channel having at least one detection cell ( 52 ; 62 ) and providing a data measurement signal, and wherein the uncoupled detection cell channel has at least two detection cells ( 52 ; 62 ) and
provides at least two data measurement signals. 2. The apparatus of claim 1, wherein the detection array has at least two rows of detection cells, and where in the coupled detection cell channel at least two ge has coupled detection cells. 3. The apparatus of claim 2, further comprising at least two adjacent coupled detection cell channels.   4. The device according to claim 2, wherein the coupled Er socket cell channels between respective non-coupled Detection cell channels are located. 5. The device of claim 2, further comprising at least two uncoupled acquisition cell channels, the coupled Detected cell channel between the non-coupled Detection cell channels is located. 6. The device of claim 1, further comprising a device device for determining a signal distribution in a z direction for the coupled detection cell channel. 7. The device according to claim 6, further comprising a device for determining the signal distribution in the z direction
in which
S _{i is} a signal obtained from a coupled channel i,
S _{Ai is} a non-coupled detection cell signal received by channel i for a detection row A,
S _Bi an uncoupled detection cell signal received by channel i for a detection row B,
S ' _{Ai is} an estimated coupled acquisition cell signal on channel i for acquisition series A and
S ' _{Bi is} an estimated coupled acquisition cell signal on channel i for acquisition series B. 8. The apparatus of claim 1, wherein the coupled sensing Solution cell channel has a detection cell. 9. The device of claim 8, wherein the coupled sensing solution cell channel between respective non-coupled Detection cell channels is located. 10. The apparatus of claim 8, further comprising a device device for determining a signal distribution in a z direction for the coupled detection cell channel. 11. The apparatus of claim 10, further comprising a device for determining the signal distribution in the z direction
in which
S _{i is} a signal obtained from a coupled channel i,
S _{Ai is} a non-coupled detection cell signal received by channel i for a detection row A,
S _Bi an uncoupled detection cell signal received by channel i for a detection row B,
S ' _{Ai is} an estimated coupled acquisition cell signal on channel i for acquisition series A and
S ' _{Bi is} an estimated coupled acquisition cell signal on channel i for acquisition series B. 12. detection array for a multi-slice computer tomography system ( 10 ), with at least one coupled channel and at least one non-coupled channel, the coupled channel at least one detection cell ( 52 ; 62 ) and the non-coupled channel at least has two detection cells. 13. The detection array of claim 12, wherein the coupled Channel has a detection cell. 14. The detection array of claim 12, further comprising two rows of detection cells, the coupled channel at least has two coupled detection cells. 15. A method for obtaining data measurement signals in a multi-slice computer tomography system, the system comprising an acquisition array ( 50 ; 60 ) with at least two channels, comprising the steps:
Obtaining a signal from at least one coupled channel of the detection array and
Determine a signal distribution in a z direction for the coupled channel. The method of claim 15, wherein each channel includes at least two sense cells ( 52 ; 62 ), and wherein obtaining a signal from a coupled channel comprises the step of summing the output signals of the sense cells of the one coupled channel. 17. The method of claim 15, wherein the coupled channel has a detection cell with a z-axis length that is approximately equal to the z-axis length of the other channels, the are formed by a plurality of detection cells, and wherein receiving a signal from the coupled channel obtaining an output signal from the one cell around sums up. 18. The method of claim 15, wherein each channel at least contains two detection cells and being obtained one Signal from at least one coupled channel the step Summing the sense cell outputs each second channel, so that a signal for every second Channel is provided. 19. The method of claim 15, wherein determining a signal distribution in the z direction for the coupled channel is performed according to
in which
S _{i is} a signal obtained from a coupled channel i,
S _Ai an uncoupled detection cell signal received from the channel i of a detection row A,
S _Bi an uncoupled detection cell signal received from the channel i of a detection row B,
S ' _{Ai is} an estimated coupled acquisition cell signal on channel i of acquisition series A and
S ' _{Bi is} an estimated coupled acquisition cell signal on channel i of acquisition row B.